Journal of High Energy Physics (Dec 2020)
Observable signatures of scotogenic Dirac model
Abstract
Abstract In this work, we make a detailed discussion on the phenomenology of the scotogenic Dirac model, which could accommodate the Dirac neutrino mass and dark matter. We have studied the lepton-flavor-violating (LFV) processes in this model, which are mediated by the charged scalar ϕ ± and heavy Dirac fermions N i . The experimental bounds, especially given by decays μ → eγ and μ → 3e, have put severe constraints on the Yukawa couplings y Φ and masses m N1, m ϕ . We select the heavy Dirac fermion N 1 as dark matter candidate and find the correct relic density will be reached basically by annihilating through another Yukawa coupling y χ . After satisfying LFV and dark matter relic density constraints, we consider the indirect detections of dark matter annihilating into leptons. But the constraints are relatively loose, only the τ + τ − channel can impose a mild excluding capability. Then we make a detailed discussion on the dark matter direct detections. Although two Yukawa couplings can both contribute to the direct detection processes, more attention has been paid on the y Φ-related processes as the y χ -related process is bounded loosely. The current and future direct detection experiments have been used to set constraints on the Yukawa couplings and masses. The current direct detections bounds are relatively loose and can barely exclude more parameter region beyond the LFV. For the future direct detection experiments, the excluding capacities can be improved due to larger exposures. The detecting capabilities in the large mass region have not been weakened as the existence of mass enhancement from the magnetic dipole operator O mag . $$ {\mathcal{O}}_{\mathrm{mag}.} $$ . At last, we have briefly discussed the collider signal searching in this model, the most promising signature is pair produced ϕ + ϕ − and decay into the signal of ℓ + ℓ − + Ɇ T . The exclusion limits from collider on m N1 and m ϕ have provided a complementary detecting capability compared to the LFV and dark matter detections.
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